Thermodynamic analysis of integrated system of ammonia-water Kalina-Rankine cycle

被引：0

作者：

Guo Z. ^{[1
]}

Chen Y. ^{[1
]}

Wu J. ^{[1
]}

Zhang Z. ^{[1
]}

机构：

[1] Key Laboratory of Energy Thermal Conversion and Control of Ministry of Education, Southeast University, Nanjing

来源：

Harbin Gongye Daxue Xuebao/Journal of Harbin Institute of Technology | 2016年 / 48卷 / 01期

关键词：

Ammonia-water; Exergy analysis; Integrated system; Kalina cycle; Rankine cycle;

D O I：

10.11918/j.issn.0367-6234.2016.01.014

中图分类号：

学科分类号：

摘要：

The thermodynamic analysis of the integrated system was conducted and the indexes of the power recovery efficiency and the exergy efficiency were chosen for system performance evaluation. The impact of inlet temperatures of both the heat resource and cooling water on the power recovery efficiency and the exergy efficiency of the system were analyzed under certain initial conditions. The exergy loss and exergy efficiency of each component of the system were demonstrated which could direct the improvement target of the system for better heat transfer performance. When the heat resource inlet temperature th1=300 ℃, the power recovery efficiencies of the Kalina cycle (cooling water tc1=25 ℃) and Rankine cycle (tc1=15 ℃) are respectively 18.2% and 14.6%, the exergy efficiencies are respectively 41.1% and 33.1%, while the composite power recovery efficiency and composite exergy efficiency of the ammonia-water Rankine cycle are respectively 19.6% and 46.5%. Moreover, when the temperature of heating water is set as 70 ℃ or 90 ℃, while the temperature of back water keeps 40 ℃, the Rankine cycle can get additional 55.3% or 65.6% heating recovery efficiency or 8.7% or 13.4% heating water exergy efficiency. © 2016, Harbin Institute of Technology. All right reserved.

引用

页码：94 / 100

页数：6

共 12 条

[1] Al-Rabghi O.M., Beirutty M., Akyurt M., Et al., Recovery and utilization of waste heat, Heat Recovery Systems and CHP, 13, 5, pp. 463-470, (1993)
[2] Radermacher R., Thermodynamic and heat transfer implications of working fluid mixtures in Rankine cycle, International Journal Heat Fluid Flow, 10, 2, pp. 90-102, (1989)
[3] Saleh B., Koglbauer G., Wendland M., Et al., Working fluids for low-temperature organic Rankine cycle, Energy, 32, 7, pp. 1210-1221, (2007)
[4] Kalina A.I., Combine-cycle system with novel bottoming cycle, Journal of Engineering for Gas Turbine and Power, 106, 4, pp. 737-742, (1984)
[5] Hua J., Chen Y., Wang Y., Et al., Thermodynamic analysis of ammonia-water power/chilling cogeneration cycle with low-grade waster heat, Applied Thermal Engineering, 64, 1-2, pp. 483-490, (2014)
[6] Hua J., Chen Y., Liu H., Et al., Thermodynamic analysis of simplified dual-pressure ammonia-water absorption power cycle, Journal of Cent South University, 19, 3, pp. 797-802, (2012)
[7] Hua J., Chen Y., Wu J., Thermal performance of a modified ammonia-water power cycle for reclaiming mid/low-grade waste heat, Energy Conversion and Management, 85, pp. 453-459, (2014)
[8] Zhang X., Mao G., Zhang Y., A review of research on the Kalina cycle, Renewable and Sustainable Energy Reviews, 16, 7, pp. 5309-5318, (2012)
[9] Bombarda P., Invernizzi C.M., Pietra C., Heat recovery from Diesel engines: A thermodynamic comparison between Kalina and ORC cycles, Applied Thermal Engineering, 30, 2-3, pp. 212-219, (2010)
[10] Zhang J., Liu J., Chen Q., Optimal evaporating temperature and exergy analysis for Organic Rankine cycle, CIESC Journal, 64, 3, pp. 820-826, (2013)

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